Charging module and winding structure

By using an automated winding structure and airflow circulation system, the problems of uneven winding and difficult cleaning of charging modules are solved, achieving efficient and stable cable winding and cleaning, and improving equipment performance and installation efficiency.

CN122143687APending Publication Date: 2026-06-05SHENZHEN EJIAYOU INFORMATION TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SHENZHEN EJIAYOU INFORMATION TECH CO LTD
Filing Date
2026-04-10
Publication Date
2026-06-05

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    Figure CN122143687A_ABST
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Abstract

The application provides a charging module and a winding structure, and relates to the field of charging piles.The charging module comprises a main plate 1, the rear side of the main plate is provided with a cross frame, the two ends of the cross frame are fixedly connected with connecting beams, the other ends of the two connecting beams are jointly connected with a front beam, and the front beam is provided with a moving seat.The application drives the wire guide plate to reciprocate stably along the limiting rod by controlling the rotation of the main shaft, and the wire straightening wheel moves synchronously to accurately guide the cable to be arranged, and the corresponding winding drum is driven to rotate synchronously by cooperating with the chain wheel and chain transmission, so that the arrangement and guidance of the cable and the automatic rotation of the winding drum are cooperated and synchronized, and it is ensured that the cable can be wound at uniform intervals and closely arranged.The reciprocating movement of the wire guide plate drives the synchronous part to drive the scraping part to move synchronously with the wire guide plate, and the surface dust of the cable is scraped in real time to cooperate with the arrangement of the cable, and the blowing and suction air flow circulation of the two opposite air shells is realized to efficiently and synchronously perform the winding and cleaning operations.
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Description

Technical Field

[0001] This invention relates to the field of charging piles, and more particularly to a charging module and winding structure. Background Technology

[0002] With the rapid development of the new energy industry, the quality of the internal cable winding of the charging module, as the core power supply component of the charging pile, directly affects the module's circuit conductivity, insulation stability, and service life. Cable winding is a critical process in charging module installation, and the requirements for uniform cable distribution, cleanliness, and operational efficiency are becoming increasingly stringent.

[0003] Existing charging modules typically employ a simple, distributed winding structure, relying on manual winding. However, manual winding is susceptible to variations in operator experience, leading to uneven cable spacing, loose arrangement, and even stacking and tension imbalances. This directly impacts the charging module's circuit performance and increases the risk of malfunctions. Furthermore, since installations are often outdoors, dust and other impurities easily accumulate on the cable surface, requiring manual cleaning and increasing installation time. Manual wiping also has limited dust removal effectiveness, leaving some dust residue on the cable surface or in the winding environment, affecting subsequent assembly accuracy and equipment operational stability.

[0004] Furthermore, during the installation of charging modules, multi-station winding operations are often required for cables at different locations. Some simple auxiliary winding tools are only moderately applicable, and switching between workstations necessitates tedious disassembly and calibration operations, which are not only time-consuming and labor-intensive but also prone to positioning deviations, affecting winding accuracy. Frequent calibration and adjustments not only increase the workload of operators but also indirectly increase the time and labor costs of the winding operation.

[0005] Therefore, it is necessary to provide a new charging module and winding structure to solve the above-mentioned technical problems. Summary of the Invention

[0006] To address the aforementioned technical problems, this invention provides a charging module and a winding structure.

[0007] The present invention provides a charging module and winding structure comprising: a main board, a crossbeam on the rear side of the main board, connecting beams fixedly connected to both ends of the crossbeam, a front beam connected to the other ends of the two connecting beams, a movable seat on the front beam, a lead plate on the movable seat, a winding wheel rotatably connected to one end of the lead plate, and multiple winding cylinders on the crossbeam; a winding cleaning mechanism comprising a vertical beam fixedly connected to the movable seat, a side frame fixedly connected to one side wall of the vertical beam, a synchronizing element between the vertical beam and the side frame, a synchronizing rod fixedly connected to one end of the synchronizing element, a driving rod fixedly connected to the other end of the synchronizing element, a scraper fixedly connected to the lower end of the driving rod, a uniform winding assembly between the lead plate and the vertical beam, and a synchronous collection assembly between the side frames.

[0008] Preferably, the synchronizing rod is slidably connected to the upper end of the vertical beam, the lower end of the synchronizing rod is fixedly connected to the guide plate, and the driving rod is slidably connected to the upper frame wall of the side frame.

[0009] Preferably, the uniform winding assembly includes a main shaft, the lower end of which is rotatably connected to a movable seat, the upper end of which is rotatably connected to a vertical beam, a limit rod fixedly connected between the vertical beam and the movable seat, a guide plate slidably connected to the limit rod, a threaded opening on the guide plate, a reciprocating lead screw at the lower end of the main shaft, and the guide plate threadedly connected to the main shaft.

[0010] Preferably, the synchronous collection component includes two opposing air housings, which are symmetrically arranged. The two opposing air housings are respectively fixedly connected to the two side walls of the side frame. A bottom box is fixedly connected to the lower end of the cross frame. A fan is installed on one side wall of the bottom box. A filter plate is installed inside the bottom box. The air outlet of the fan is connected to one opposing air housing through a first connecting pipe. The other opposing air housing is connected to the other side wall of the bottom box through a second connecting pipe.

[0011] Preferably, an extension frame is fixedly connected to the upper end of the vertical beam, and a main motor is installed and connected to the upper end of the extension frame. The output end of the main motor is fixedly connected to the main shaft.

[0012] Preferably, two side ears are symmetrically provided at the upper end of the cross frame, two stabilizing rods are fixedly connected between the two side ears, a follower block is slidably connected between the two stabilizing rods, an mounting cylinder is provided on the follower block, an upper tube is rotatably connected in the mounting cylinder, the upper tube is located above multiple winding drums, a triangular opening is provided at the upper end axis of each of the multiple winding drums, a sprocket is fixedly connected to both the upper tube and the main shaft, a chain is installed between two sprockets, and a locking assembly is provided inside the upper tube.

[0013] Preferably, the locking assembly includes a triangular locking rod, which is slidably connected to the lower end wall of the upper tube. An internal plate is fixedly connected to the upper end of the triangular locking rod. The internal plate is located inside the upper tube. An adjusting short shaft is rotatably connected to the internal plate. The adjusting short shaft is a threaded rod. A threaded opening is provided at the upper end wall of the upper tube. The adjusting short shaft is threadedly connected to the upper end wall of the upper tube. A handle is provided at the top of the adjusting short shaft.

[0014] Preferably, both ends of the front beam are fixedly connected to lower plates, and a horizontal long rod is fixedly connected between the two lower plates. The lower end of the movable seat is provided with a driving block. The front beam is provided with a through-strip opening, and the driving block extends into the through-strip opening. The driving block is slidably connected to the horizontal long rod. An embedded shaft is rotatably connected to the through-strip opening. One end of the front beam is installed with an auxiliary motor, and the output end of the auxiliary motor is fixedly connected to the embedded shaft. The driving block is provided with a threaded opening, and the embedded shaft is a threaded rod. The driving block is threadedly connected to the embedded shaft. The upper end of the extension frame is provided with a strip frame, and one end of the strip frame is fixedly connected to the accompanying block.

[0015] A charging module includes a module body, cable components, and docking terminals. The cable components can be uniformly wound and installed using any of the above-described winding structures. The module body is encapsulated in a cuboid shell. The main board in the module body is fixedly connected to the inner wall of the shell. The cable components wound on multiple winding drums are electrically connected to the docking terminals.

[0016] Compared with related technologies, the charging module and winding structure provided by the present invention have the following beneficial effects: 1. This invention controls the main shaft to rotate, and its lower reciprocating screw drives the lead plate to reciprocate smoothly along the limit rod. The winding wheel moves synchronously to accurately guide the cable placement. At the same time, the sprocket at the upper end of the main shaft, in conjunction with the chain, further drives the sprocket on the upper tube to rotate, so as to drive the upper tube and the winding drum to rotate synchronously. This forms a coordinated action between the cable placement guide and the automatic rotation of the winding drum, ensuring that the cable can be wound with uniform spacing and tightly arranged. This effectively avoids some problems such as stacking, looseness or uneven tension that occur during manual winding, and provides a reliable guarantee for the circuit conductivity and insulation of the charging module. 2. This invention drives the synchronous rod and the synchronous component and drive rod to move together through the reciprocating movement of the conductor plate. The scraper at the lower end of the drive rod is in the side frame and moves synchronously with the conductor plate. It works in real time to scrape off the dust on the cable surface in coordination with the cable layout. This allows the winding and cleaning of the cable to be carried out simultaneously, which not only eliminates the need for a separate cleaning step and improves the efficiency of installation and winding, but also ensures that there is not too much dust between the installed and wound cables, which would affect the cable layout environment. 3. This invention activates the fan on the side wall of the bottom box, and the generated airflow is delivered to the opposing air shell on one side through the first connecting pipe. The opposing air shell on the other side uses the second connecting pipe to form a negative pressure adsorption, realizing a blowing and sucking airflow circulation in the space within the side frame. The dust that is scraped off is quickly collected and directly intercepted and collected by the filter plate, realizing efficient and simultaneous winding and cleaning operations. This can effectively prevent dust from adhering and affecting the cable quality or subsequent assembly environment. 4. This invention uses a throttle to rotate the adjusting short shaft, allowing the triangular locking rod to engage or unlock with the triangular opening at the center axis of the winding drum. The operation is quick and simple. The auxiliary motor then drives the embedded shaft to rotate, and the threaded transmission causes the drive block and the moving seat to slide smoothly along the front beam and the stabilizing rod. This allows for precise adjustment of the relative position of the upper tube and the target winding drum based on the position of the moving seat. The switching process is quick and stable, adapting to the cable winding needs at different locations and greatly expanding the application scenarios of the equipment. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of a preferred embodiment of the present invention; Figure 2 for Figure 1 The diagram shown is a structural schematic of the winding cleaning mechanism. Figure 3 for Figure 2 The diagram shows the structure at point A. Figure 4 for Figure 3 The diagram shows the structure of the conductor plate. Figure 5 for Figure 3 The diagram shows the structure of the synchronizing element. Figure 6 for Figure 2 The diagram shows the structure at point B. Figure 7 for Figure 6 The diagram shows the internal structure of the upper tube. Figure 8 for Figure 2 The diagram shows the structure of the bottom box.

[0018] Numbered components in the diagram: 1. Main board; 2. Horizontal frame; 21. Connecting beam; 22. Front beam; 3. Moving seat; 31. Guide plate; 32. Winding wheel; 33. Winding spool; 4. Vertical beam; 41. Side frame; 42. Synchronizing component; 421. Synchronizing rod; 422. Drive rod; 43. Scraper; 44. Main shaft; 45. Limiting rod; 46. Opposite fan casing; 5. Bottom box; 51. Fan; 52. 6. Filter screen; 6. Extension frame; 61. Main motor; 62. Side lug; 63. Stabilizer bar; 64. Follower block; 641. Mounting cylinder; 65. Top tube; 7. Sprocket; 71. Chain; 72. Triangular locking rod; 73. Internal plate; 74. Adjustment short shaft; 75. Throttle; 8. Lower plate; 81. Horizontal long bar; 82. Drive block; 83. Embedded shaft; 84. Auxiliary motor; 9. Housing. Detailed Implementation

[0019] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0020] Please refer to the following: Figures 1 to 8 A charging module and winding structure includes: a main board 1, a crossbeam 2 on the rear side of the main board 1, connecting beams 21 fixedly connected to both ends of the crossbeam 2, a front beam 22 connected to the other end of the two connecting beams 21, a movable seat 3 on the front beam 22, a wire guide plate 31 on the movable seat 3, a winding wheel 32 rotatably connected to one end of the wire guide plate 31, and multiple winding cylinders 33 on the crossbeam 2; a winding cleaning mechanism, including a vertical beam 4, fixedly connected to the movable seat 3, a side frame 41 fixedly connected to one side wall of the vertical beam 4, a synchronizing element 42 between the vertical beam 4 and the side frame 41, a synchronizing rod 421 fixedly connected to one end of the synchronizing element 42, a driving rod 422 fixedly connected to the other end of the synchronizing element 42, a scraper 43 fixedly connected to the lower end of the driving rod 422, a uniform winding assembly between the wire guide plate 31 and the vertical beam 4, and a synchronous collection assembly between the side frames 41.

[0021] In the specific implementation process, such as Figure 3 and Figure 5 As shown, the synchronizing rod 421 is slidably connected to the upper end of the vertical beam 4, the lower end of the synchronizing rod 421 is fixedly connected to the guide plate 31, and the driving rod 422 is slidably connected to the upper end of the side frame 41.

[0022] It should be noted that the conductor plate 31 slides back and forth alternately between the movable seat 3 and the vertical beam 4, so that the winding wheel 32 on the conductor plate 31 moves synchronously, providing a guide for the cable to be evenly distributed in position. Synchronous rod 421 and drive rod 422 form an integrated structure through synchronous component 42. When the conductor plate 31 moves back and forth, synchronous rod 421 drives synchronous component 42 to move. Drive rod 422 at the other end of synchronous component 42 slides relative to the upper frame wall of side frame 41. Scraper 43 at the lower end of drive rod 422 moves synchronously, and can directly scrape off dust from the surface of the cable during the cable winding process. The scraper 43 is made of a composite material of silicone and wear-resistant fiber, which ensures effective dust removal while avoiding damage to the cable insulation layer.

[0023] refer to Figure 3 and Figure 4 As shown, the uniform winding assembly includes a main shaft 44, the lower end of which is rotatably connected to a movable seat 3, and the upper end of which is rotatably connected to a vertical beam 4. A limit rod 45 is fixedly connected between the vertical beam 4 and the movable seat 3. A guide plate 31 is slidably connected to the limit rod 45. The guide plate 31 is provided with a threaded opening. The lower end of the main shaft 44 is a reciprocating lead screw. The guide plate 31 is threadedly connected to the main shaft 44.

[0024] It should be noted that: the drive spindle 44 rotates, and the reciprocating screw structure at the lower end of the spindle 44 can drive the conductor plate 31 to slide back and forth along the limit rod 45, so that the winding wheel 32 on the conductor plate 31 moves synchronously, providing guidance for the uniform position distribution of the cable, and ensuring that cables of different specifications can be evenly arranged.

[0025] refer to Figure 3 and Figure 8 As shown, the synchronous collection component includes two opposing air housings 46, which are symmetrically arranged. The two opposing air housings 46 are fixedly connected to the two side walls of the side frame 41 respectively. A bottom box 5 is fixedly connected to the lower end of the cross frame 2. A fan 51 is installed on one side wall of the bottom box 5. A filter plate 52 is installed inside the bottom box 5. The air outlet of the fan 51 is connected to one opposing air housing 46 through a first connecting pipe. The other opposing air housing 46 is connected to the other side wall of the bottom box 5 through a second connecting pipe.

[0026] It should be noted that the air outlet of the opposing air housing 46 is square in shape and is fixedly installed on the two side frame walls of the side frame 41 to ensure that the airflow is accurately applied to the dust removal area. At the same time, the fan 51 on the side wall of the bottom box 5 is started. The airflow generated by the fan 51 is transported to the opposing air shell 46 on one side through the first connecting pipe. The opposing air shell 46 on the other side uses the second connecting pipe to form a negative pressure adsorption, so that the space in the side frame 41 forms a blowing and sucking airflow cycle, collecting the scraped dust into the bottom box 5, and completing the dust recovery by blocking the filter plate 52.

[0027] refer to Figure 2 and Figure 6As shown, an extension frame 6 is fixedly connected to the upper end of the vertical beam 4, and a main motor 61 is installed and connected to the upper end of the extension frame 6. The output end of the main motor 61 is fixedly connected to the main shaft 44.

[0028] It should be noted that the extension frame 6 and the vertical beam 4 are a fixed integrated structure, ensuring that the output end of the main motor 61 can stably drive the main shaft 44 to rotate.

[0029] refer to Figure 2 and Figure 6 As shown, two side ears 62 are symmetrically provided at the upper end of the cross frame 2. Two stabilizing rods 63 are fixedly connected between the two side ears 62. A following block 64 is slidably connected between the two stabilizing rods 63. An installation cylinder 641 is provided on the following block 64. An upper tube 65 is rotatably connected in the installation cylinder 641. The upper tube 65 is located above multiple winding drums 33. A triangular opening is provided at the upper end of the shaft of multiple winding drums 33. A sprocket 7 is fixedly connected to both the upper tube 65 and the main shaft 44. A chain 71 is installed between the two sprockets 7. A locking component is provided inside the upper tube 65.

[0030] It should be noted that: the main shaft 44 uses the transmission action between the two sprockets 7 and the chain 71 to drive the upper tube 65 to rotate synchronously. The upper tube 65 uses the triangular clamp 72 to engage with the triangular opening at the central shaft position of the winding drum 33, thereby driving the winding drum 33 to rotate synchronously. Under the positioning guidance of the winding wheel 32 and the rotation action of the winding drum 33, the cable can be evenly wound on the winding drum 33. The two stabilizer bars 63 ensure that the trailing block 64 slides smoothly without deviation; The triangular opening of the winding drum 33 and the triangular clamp 72 work together to ensure reliable synchronous torque transmission between the upper tube 65 and the winding drum 33.

[0031] refer to Figure 6 and Figure 7 As shown, the locking assembly includes a triangular locking rod 72, which is slidably connected to the lower end wall of the upper tube 65. An inner plate 73 is fixedly connected to the upper end of the triangular locking rod 72. The inner plate 73 is located inside the upper tube 65. An adjusting short shaft 74 is rotatably connected to the inner plate 73. The adjusting short shaft 74 is a threaded rod. A threaded opening is provided at the upper end wall of the upper tube 65. The adjusting short shaft 74 is threadedly connected to the upper end wall of the upper tube 65. A handle 75 is provided at the top of the adjusting short shaft 74.

[0032] It should be noted that: rotating the handle 75 causes the adjusting short shaft 74 to rotate. The adjusting short shaft 74 moves up and down relative to the upper end of the upper tube wall of the upper tube 65 according to the thread action, thereby pushing the inner plate 73 and the triangular locking rod 72 to slide relatively stably, so that the lower end of the triangular locking rod 72 slides away from the triangular opening at the current center axis position of the winding drum 33, so as to release the lock. Rotate the lever in the opposite direction by 75 rpm to engage the triangular locking rod 72 with the triangular opening at the center axis position of the target winding drum 33, thus completing the locking.

[0033] refer to Figure 2 and Figure 3 As shown, both ends of the front beam 22 are fixedly connected to lower plates 8, and a horizontal long rod 81 is fixedly connected between the two lower plates 8. The lower end of the movable seat 3 is provided with a drive block 82. The front beam 22 is provided with a through strip opening, and the drive block 82 extends into the through strip opening. The drive block 82 is slidably connected to the horizontal long rod 81. An embedded shaft 83 is rotatably connected in the through strip opening. One end of the front beam 22 is installed and connected to an auxiliary motor 84. The output end of the auxiliary motor 84 is fixedly connected to the embedded shaft 83. The drive block 82 is provided with a threaded opening, and the embedded shaft 83 is a threaded rod. The drive block 82 is threadedly connected to the embedded shaft 83. The upper end of the extension frame 6 is provided with a strip frame, and one end of the strip frame is fixedly connected to the following block 64.

[0034] It should be noted that: when the auxiliary motor 84 is started, the output end of the auxiliary motor 84 drives the embedded shaft 83 to rotate. The embedded shaft 83 drives the drive block 82 to slide stably along the horizontal rod 81 according to the thread action. The movable seat 3 connected to the drive block 82 moves synchronously along the front beam 22. The movable seat 3 drives the vertical beam 4, the extension frame 6 and the accompanying block 64 to slide stably along the stabilizing rod 63. On the one hand, the movable seat 3 can be adjusted to drive the winding wheel 32 to adjust the wiring position. On the other hand, the upper tube 65 can be adjusted to the position above the target winding drum 33.

[0035] A charging module includes a module body, cable components, and docking terminals. The cable components can be uniformly wound and installed using any of the above-mentioned winding structures. The module body is encapsulated in a cuboid shell 9. The main board 1 in the module body is fixedly connected to the inner wall of the shell 9. The cable components wound on multiple winding cylinders 33 are electrically connected to the docking terminals.

[0036] The working principle of the charging module and winding structure provided by the present invention is as follows: First, according to the position of the cable to be wound, the lock between the upper tube 65 and the current winding drum 33 is released in advance. That is, the throttle handle 75 is operated to drive the adjusting short shaft 74 to rotate. The adjusting short shaft 74 moves up and down relative to the upper end tube wall of the upper tube 65 according to the thread action, thereby pushing the built-in plate 73 and the triangular locking rod 72 to slide relatively stably, so that the lower end of the triangular locking rod 72 slides away from the triangular opening at the central axis position of the current winding drum 33, so as to release the lock. Then, the auxiliary motor 84 is started, causing the output end of the auxiliary motor 84 to drive the embedded shaft 83 to rotate. The embedded shaft 83 drives the drive block 82 to slide stably along the horizontal rod 81 according to the thread action. The movable seat 3 connected to the drive block 82 moves synchronously along the front beam 22, and the movable seat 3 drives the vertical beam 4, the extension frame 6 and the accompanying block 64 to slide stably along the stabilizing rod 63. The upper tube 65 is adjusted to the position above the target winding drum 33, and then the 75 throttle is rotated in the opposite direction to make the triangular clamp 72 engage with the triangular opening at the center axis position of the target winding drum 33. This allows for a quick and stable completion of the winding position switching and the continuation of further winding operations.

[0037] When the main motor 61 is started, its output drives the main shaft 44 to rotate. On the one hand, the reciprocating screw structure at the lower end of the main shaft 44 drives the guide plate 31 to slide back and forth along the limiting rod 45. The winding wheel 32 on the guide plate 31 moves synchronously, providing guidance for the uniform position distribution of the cable. On the other hand, the main shaft 44 uses the transmission action between the two sprockets 7 and the chain 71 to drive the upper tube 65 to rotate synchronously. The upper tube 65 uses the triangular clamp 72 to engage with the triangular opening at the central axis position of the winding drum 33, thereby driving the winding drum 33 to rotate synchronously. Under the positioning guidance of the winding wheel 32 and the rotation action of the winding drum 33, the cable can be evenly wound on the winding drum 33. When the conductor plate 31 moves back and forth, the synchronizing rod 421 drives the synchronizing component 42 to move. The driving rod 422 at the other end of the synchronizing component 42 slides relative to the upper frame wall of the side frame 41. The scraper 43 at the lower end of the driving rod 422 moves synchronously, and can directly scrape off the dust on the surface of the cable during the cable winding process.

[0038] At the same time, the fan 51 on the side wall of the bottom box 5 is started. The airflow generated by the fan 51 is transported to the opposing air shell 46 on one side through the first connecting pipe. The opposing air shell 46 on the other side uses the second connecting pipe to form a negative pressure adsorption, so that the space in the side frame 41 forms a blowing and sucking airflow cycle, collecting the scraped dust into the bottom box 5, and completing the dust recovery by blocking the filter plate 52.

[0039] The above description is merely an embodiment of the present invention and does not limit the patent scope of the present invention. Any equivalent structural or procedural transformations made based on the content of the present invention specification and drawings, or direct or indirect applications in other related technical fields, are similarly included within the patent protection scope of the present invention.

Claims

1. A winding structure for a charging module, characterized in that, include: Main board (1), a cross frame (2) is provided on the rear side of the main board (1), and a connecting beam (21) is fixedly connected to both ends of the cross frame (2). The other ends of the two connecting beams (21) are connected to a front beam (22). A movable seat (3) is provided on the front beam (22). A wire guide plate (31) is provided on the movable seat (3). A winding wheel (32) is rotatably connected to one end of the wire guide plate (31). Multiple winding drums (33) are provided on the cross frame (2). The winding cleaning mechanism includes a vertical beam (4), which is fixedly connected to a movable seat (3). A side frame (41) is fixedly connected to one side wall of the vertical beam (4). A synchronizing element (42) is provided between the vertical beam (4) and the side frame (41). A synchronizing rod (421) is fixedly connected to one end of the synchronizing element (42). A driving rod (422) is fixedly connected to the other end of the synchronizing element (42). A scraper (43) is fixedly connected to the lower end of the driving rod (422). A uniform winding assembly is provided between the conductor plate (31) and the vertical beam (4). A synchronous collection assembly is provided between the side frames (41).

2. The winding structure of a charging module according to claim 1, characterized in that, The synchronizing rod (421) is slidably connected to the upper end of the vertical beam (4), the lower end of the synchronizing rod (421) is fixedly connected to the guide plate (31), and the driving rod (422) is slidably connected to the upper end of the side frame (41).

3. The winding structure of a charging module according to claim 1, characterized in that, The uniform winding assembly includes a main shaft (44), the lower end of which is rotatably connected to a movable seat (3), the upper end of which is rotatably connected to a vertical beam (4), a limit rod (45) is fixedly connected between the vertical beam (4) and the movable seat (3), the guide plate (31) is slidably connected to the limit rod (45), the guide plate (31) is provided with a threaded opening, the lower end of the main shaft (44) is a reciprocating lead screw, and the guide plate (31) is threadedly connected to the main shaft (44).

4. The winding structure of a charging module according to claim 1, characterized in that, The synchronous collection component includes two opposing air housings (46), which are symmetrically arranged. The two opposing air housings (46) are fixedly connected to the two side walls of the side frame (41) respectively. A bottom box (5) is fixedly connected to the lower end of the cross frame (2). A fan (51) is installed on one side wall of the bottom box (5). A filter plate (52) is installed inside the bottom box (5). The air outlet of the fan (51) is connected to one opposing air housing (46) through a first connecting pipe. The other opposing air housing (46) is connected to the other side wall of the bottom box (5) through a second connecting pipe.

5. The winding structure of a charging module according to claim 3, characterized in that, An extension frame (6) is fixedly connected to the upper end of the vertical beam (4), and a main motor (61) is installed and connected to the upper end of the extension frame (6). The output end of the main motor (61) is fixedly connected to the main shaft (44).

6. The winding structure of a charging module according to claim 1, characterized in that, Two side ears (62) are symmetrically provided at the upper end of the cross frame (2). Two stabilizing rods (63) are fixedly connected between the two side ears (62). A follower block (64) is slidably connected between the two stabilizing rods (63). An installation cylinder (641) is provided on the follower block (64). An upper tube (65) is rotatably connected in the installation cylinder (641). The upper tube (65) is located above multiple winding bobbins (33). A triangular opening is provided at the upper axis of each of the multiple winding bobbins (33). A sprocket (7) is fixedly connected to both the upper tube (65) and the main shaft (44). A chain (71) is installed between the two sprockets (7). A locking component is provided inside the upper tube (65).

7. The winding structure of a charging module according to claim 6, characterized in that, The locking assembly includes a triangular locking rod (72), which is slidably connected to the lower end wall of the upper tube (65). An internal plate (73) is fixedly connected to the upper end of the triangular locking rod (72). The internal plate (73) is located inside the upper tube (65). An adjusting short shaft (74) is rotatably connected to the internal plate (73). The adjusting short shaft (74) is a threaded rod. A threaded opening is provided at the upper end wall of the upper tube (65). The adjusting short shaft (74) is threadedly connected to the upper end wall of the upper tube (65). A handle (75) is provided at the top of the adjusting short shaft (74).

8. The winding structure of a charging module according to claim 5, characterized in that, Both ends of the front beam (22) are fixedly connected to the lower plate (8), and the two lower plates (8) are fixedly connected to the horizontal long rod (81). The lower end of the moving seat (3) is provided with a driving block (82). The front beam (22) is provided with a through strip opening. The driving block (82) extends into the through strip opening. The driving block (82) is slidably connected to the horizontal long rod (81). The through strip opening is rotatably connected to the embedded shaft (83). One end of the front beam (22) is installed with an auxiliary motor (84). The output end of the auxiliary motor (84) is fixedly connected to the embedded shaft (83). The driving block (82) is provided with a threaded opening. The embedded shaft (83) is a threaded rod. The driving block (82) is threadedly connected to the embedded shaft (83). The upper end of the extension frame (6) is provided with a strip frame. One end of the strip frame is fixedly connected to the accompanying block (64).

9. A charging module, characterized in that, The module includes a main body, cable components and docking terminals. The cable components can be uniformly wound and installed using the winding structure described in any one of claims 1-8. The main body of the module is encapsulated in a cuboid shell (9). The main board (1) in the main body of the module is fixedly connected to the inner wall of the shell (9). The cable components wound on multiple winding drums (33) are electrically connected to the docking terminals.